////////////////////////////////////////////////////////////////////// // LibFile: matrices.scad // Matrix math and affine transformation matrices. // To use, add the following lines to the beginning of your file: // ``` // use // ``` ////////////////////////////////////////////////////////////////////// // Section: Matrix Manipulation // Function: ident() // Description: Create an `n` by `n` identity matrix. // Arguments: // n = The size of the identity matrix square, `n` by `n`. function ident(n) = [for (i = [0:n-1]) [for (j = [0:n-1]) (i==j)?1:0]]; // Function: affine2d_to_affine3d() // Description: Takes a 3x3 affine2d matrix and returns its 4x4 affine3d equivalent. function mat3_to_mat4(m) = concat( [for (r = [0:2]) concat( [for (c = [0:2]) m[r][c]], [0] ) ], [[0, 0, 0, 1]] ); // Section: Affine2d 3x3 Transformation Matrices // Function: affine2d_identity() // Description: Create a 3x3 affine2d identity matrix. function affine2d_identity() = ident(3); // Function: affine2d_translate() // Description: // Returns the 3x3 affine2d matrix to perform a 2D translation. // Arguments: // v = 2D Offset to translate by. [X,Y] function affine2d_translate(v) = [ [1, 0, v.x], [0, 1, v.y], [0 ,0, 1] ]; // Function: affine2d_scale() // Description: // Returns the 3x3 affine2d matrix to perform a 2D scaling transformation. // Arguments: // v = 2D vector of scaling factors. [X,Y] function affine2d_scale(v) = [ [v.x, 0, 0], [ 0, v.y, 0], [ 0, 0, 1] ]; // Function: affine2d_zrot() // Description: // Returns the 3x3 affine2d matrix to perform a rotation of a 2D vector around the Z axis. // Arguments: // ang = Number of degrees to rotate. function affine2d_zrot(ang) = [ [cos(ang), -sin(ang), 0], [sin(ang), cos(ang), 0], [ 0, 0, 1] ]; // Function: affine2d_skew() // Usage: // affine2d_skew(xa, ya) // Description: // Returns the 3x3 affine2d matrix to skew a 2D vector along the XY plane. // Arguments: // xa = Skew angle, in degrees, in the direction of the X axis. // ya = Skew angle, in degrees, in the direction of the Y axis. function affine2d_skew(xa, ya) = [ [1, tan(xa), 0], [tan(ya), 1, 0], [0, 0, 1] ]; // Function: affine2d_chain() // Usage: // affine2d_chain(affines) // Description: // Returns a 3x3 affine2d transformation matrix which results from applying each matrix in `affines` in order. // Arguments: // affines = A list of 3x3 affine2d matrices. function affine2d_chain(affines, _m=undef, _i=0) = (_i>=len(affines))? (is_undef(_m)? ident(3) : _m) : affine2d_chain(affines, _m=(is_undef(_m)? affines[_i] : affines[_i] * _m), _i=_i+1); // Function: affine2d_apply() // Usage: // affine2d_apply(pts, affines) // Description: // Given a list of 3x3 affine2d transformation matrices, applies them in order to the points in the point list. // Arguments: // pts = A list of 2D points to transform. // affines = A list of 3x3 affine2d matrices to apply, in order. // Example: // npts = affine2d_apply( // pts = [for (x=[0:3]) [5*x,0]], // affines =[ // affine2d_scale([3,1]), // affine2d_rot(90), // affine2d_translate([5,5]) // ] // ); // Returns [[5,5], [5,20], [5,35], [5,50]] function affine2d_apply(pts, affines) = let(m = affine2d_chain(affines)) [for (p = pts) point2d(m * concat(point2d(p),[1]))]; // Section: Affine3d 4x4 Transformation Matrices // Function: affine3d_identity() // Description: Create a 4x4 affine3d identity matrix. function affine3d_identity() = ident(4); // Function: affine3d_translate() // Description: // Returns the 4x4 affine3d matrix to perform a 3D translation. // Arguments: // v = 3D offset to translate by. [X,Y,Z] function affine3d_translate(v) = [ [1, 0, 0, v.x], [0, 1, 0, v.y], [0, 0, 1, v.z], [0 ,0, 0, 1] ]; // Function: affine3d_scale() // Description: // Returns the 4x4 affine3d matrix to perform a 3D scaling transformation. // Arguments: // v = 3D vector of scaling factors. [X,Y,Z] function affine3d_scale(v) = [ [v.x, 0, 0, 0], [ 0, v.y, 0, 0], [ 0, 0, v.z, 0], [ 0, 0, 0, 1] ]; // Function: affine3d_xrot() // Description: // Returns the 4x4 affine3d matrix to perform a rotation of a 3D vector around the X axis. // Arguments: // ang = number of degrees to rotate. function affine3d_xrot(ang) = [ [1, 0, 0, 0], [0, cos(ang), -sin(ang), 0], [0, sin(ang), cos(ang), 0], [0, 0, 0, 1] ]; // Function: affine3d_yrot() // Description: // Returns the 4x4 affine3d matrix to perform a rotation of a 3D vector around the Y axis. // Arguments: // ang = Number of degrees to rotate. function affine3d_yrot(ang) = [ [ cos(ang), 0, sin(ang), 0], [ 0, 1, 0, 0], [-sin(ang), 0, cos(ang), 0], [ 0, 0, 0, 1] ]; // Function: affine3d_zrot() // Usage: // affine3d_zrot(ang) // Description: // Returns the 4x4 affine3d matrix to perform a rotation of a 3D vector around the Z axis. // Arguments: // ang = number of degrees to rotate. function affine3d_zrot(ang) = [ [cos(ang), -sin(ang), 0, 0], [sin(ang), cos(ang), 0, 0], [ 0, 0, 1, 0], [ 0, 0, 0, 1] ]; // Function: affine3d_rot_by_axis() // Usage: // affine3d_rot_by_axis(u, ang); // Description: // Returns the 4x4 affine3d matrix to perform a rotation of a 3D vector around an axis. // Arguments: // u = 3D axis vector to rotate around. // ang = number of degrees to rotate. function affine3d_rot_by_axis(u, ang) = let( u = normalize(u), c = cos(ang), c2 = 1-c, s = sin(ang) ) [ [u[0]*u[0]*c2+c , u[0]*u[1]*c2-u[2]*s, u[0]*u[2]*c2+u[1]*s, 0], [u[1]*u[0]*c2+u[2]*s, u[1]*u[1]*c2+c , u[1]*u[2]*c2-u[0]*s, 0], [u[2]*u[0]*c2-u[1]*s, u[2]*u[1]*c2+u[0]*s, u[2]*u[2]*c2+c , 0], [ 0, 0, 0, 1] ]; // Function: affine3d_skew_xy() // Usage: // affine3d_skew_xy(xa, ya) // Description: // Returns the 4x4 affine3d matrix to perform a skew transformation along the XY plane.. // Arguments: // xa = Skew angle, in degrees, in the direction of the X axis. // ya = Skew angle, in degrees, in the direction of the Y axis. function affine3d_skew_xy(xa, ya) = [ [1, 0, tan(xa), 0], [0, 1, tan(ya), 0], [0, 0, 1, 0], [0, 0, 0, 1] ]; // Function: affine3d_skew_xz() // Usage: // affine3d_skew_xz(xa, za) // Description: // Returns the 4x4 affine3d matrix to perform a skew transformation along the XZ plane. // Arguments: // xa = Skew angle, in degrees, in the direction of the X axis. // za = Skew angle, in degrees, in the direction of the Z axis. function affine3d_skew_xz(xa, za) = [ [1, tan(xa), 0, 0], [0, 1, 0, 0], [0, tan(za), 1, 0], [0, 0, 0, 1] ]; // Function: affine3d_skew_yz() // Usage: // affine3d_skew_yz(ya, za) // Description: // Returns the 4x4 affine3d matrix to perform a skew transformation along the YZ plane. // Arguments: // ya = Skew angle, in degrees, in the direction of the Y axis. // za = Skew angle, in degrees, in the direction of the Z axis. function affine3d_skew_yz(ya, za) = [ [ 1, 0, 0, 0], [tan(ya), 1, 0, 0], [tan(za), 0, 1, 0], [ 0, 0, 0, 1] ]; // Function: affine3d_chain() // Usage: // affine3d_chain(affines) // Description: // Returns a 4x4 affine3d transformation matrix which results from applying each matrix in `affines` in order. // Arguments: // affines = A list of 4x4 affine3d matrices. function affine3d_chain(affines, _m=undef, _i=0) = (_i>=len(affines))? (is_undef(_m)? ident(4) : _m) : affine3d_chain(affines, _m=(is_undef(_m)? affines[_i] : affines[_i] * _m), _i=_i+1); // Function: affine3d_apply() // Usage: // affine3d_apply(pts, affines) // Description: // Given a list of affine3d transformation matrices, applies them in order to the points in the point list. // Arguments: // pts = A list of 3D points to transform. // affines = A list of 4x4 matrices to apply, in order. // Example: // npts = affine3d_apply( // pts = [for (x=[0:3]) [5*x,0,0]], // affines =[ // affine3d_scale([2,1,1]), // affine3d_zrot(90), // affine3d_translate([5,5,10]) // ] // ); // Returns [[5,5,10], [5,15,10], [5,25,10], [5,35,10]] function affine3d_apply(pts, affines) = let(m = affine3d_chain(affines)) [for (p = pts) point3d(m * concat(point3d(p),[1]))]; // vim: noexpandtab tabstop=4 shiftwidth=4 softtabstop=4 nowrap